Nodulation Induces Systemic Resistance of Medicago truncatula and Pisum sativum Against Erysiphe pisi and Primes for Powdery Mildew-Triggered Salicylic Acid Accumulation

Smigielski, Lara; Laubach, Eva-Maria; Pesch, Lina; Glock, Joanna; Albrecht, Frank; Slusarenko, Alan; Panstruga, Ralph; Kühn, Harald

doi:10.1094/mpmi-11-18-0304-r

Cited by 27 publications

(20 citation statements)

References 145 publications

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“…Inoculation of barley with Pseudomonas spp., for example, increased crop resistance to the fungal pathogen Gaeumanomyces graminis, the causal agent of take-all disease (Fr€ ohlich et al, 2012). In Medicago truncatula, the AM fungus Rhizosphagus irregularis enhanced resistance to Xanthomonas campestris, and rhizobia increased resistance to Erysiphe pisi (Liu et al, 2007;Smigielski et al, 2019). In several cases, microbial mixtures have a more pronounced and consistent effect than inoculation with single strains.…”

Section: Functions Of Beneficial Microbes and Similarities To Pathogensmentioning

confidence: 99%

Systems Biology of Plant-Microbiome Interactions

et al. 2019

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In natural environments, plants are exposed to diverse microbiota that they interact with in complex ways. While plant-pathogen interactions have been intensely studied to understand defense mechanisms in plants, many microbes and microbial communities can have substantial beneficial effects on their plant host. Such beneficial effects include improved acquisition of nutrients, accelerated growth, resilience against pathogens, and improved resistance against abiotic stress conditions such as heat, drought, and salinity. However, the beneficial effects of bacterial strains or consortia on their host are often cultivar and species specific, posing an obstacle to their general application. Remarkably, many of the signals that trigger plant immune responses are molecularly highly similar and often identical in pathogenic and beneficial microbes. Thus, it is unclear what determines the outcome of a particular microbe-host interaction and which factors enable plants to distinguish beneficials from pathogens. To unravel the complex network of genetic, microbial, and metabolic interactions, including the signaling events mediating microbe-host interactions, comprehensive quantitative systems biology approaches will be needed.

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Section: Functions Of Beneficial Microbes and Similarities To Pathogensmentioning

confidence: 99%

Systems Biology of Plant-Microbiome Interactions

et al. 2019

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“…Many works provide data supporting the notion that inoculation of legumes with rhizobia results in the induction of an increased defense response effective against diverse pathogens (necrotrophs, biotrophs) and herbivores (Arfaoui et al 2005(Arfaoui et al , 2006(Arfaoui et al , 2007Chakraborty and Chakraborty 1989;Diaz-Valle et al 2019;Dutta et al 2008;Figueredo et al 2014Figueredo et al , 2017Kalantari et al 2018;Mabrouk et al 2007;Osdaghi et al 2011;Rabie 1998;Smigielski et al 2019) (Table 1). This effect was also observed in non legumes after rhizobial inoculation (Mishra et al 2006;Reitz et al 2000).…”

Section: Isr -Like Responses Displayed By Rhizobiamentioning

confidence: 88%

“…However, the role of JA as long distance signal of ISR and the importance of SA and JA -mediated signaling in rhizobium -legume symbiosis have not been demonstrated (Beardon et al 2014;Gutjahr and Paszkowski 2009). Interestingly, priming for SA accumulation and SA -mediated defense active against the powdery mildew fungi (biotroph) was observed in Medicago plants after rhizobial inoculation (Smigielski et al 2019). Moreover, even when suppression of SA -dependent defense responses seems to be widespread in rhizobial symbiosis, transcriptomic data indicates that peanut increase SA response during symbiosis development.…”

Section: Local Responses Induced By Rhizobia Leading To Systemic Resistancementioning

confidence: 99%

Induced systemic resistance -like responses elicited by rhizobia

et al. 2020

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Background Rhizobia are soil bacteria that engage into a mutualistic symbiosis with plants and benefit the host by fixing atmospheric N. In addition, rhizobia can be considered as biocontrol agents, contributing to plant health through direct inhibition of a wide range of pathogens. More recently, it became evident that rhizobial invasion of plant roots can also trigger an increased systemic resistance state in the host, a process resembling the Induced Systemic Resistance (ISR) mechanism. However, this indirect biocontrol property of rhizobia was relatively less explored. Scope In this review article, we present an overview of the current knowledge of ISR -like responses induced by rhizobia, considering general characteristics of this phenomenon, discussing the molecular pathways leading to this response and highlighting potential links between ISR -like responses and the nodulation signaling pathway. Conclusions A more detailed knowledge of these responses can result in development of biotechnological tools for sustainable crop production, through optimization of the systemic protective effect conferred by rhizobia.

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“…A later study performed on peas ( Pisum sativum ) and barrel medics ( Medicago truncatula Gaertn.) suggests that root symbiosis with rhizobia systemically primes plants for the salicylic-acid accumulation and defense-gene expression triggered by powdery mildew [ 90 ].…”

Section: The Art Of Warmentioning

confidence: 99%

War and Peas: Molecular Bases of Resistance to Powdery Mildew in Pea (Pisum sativum L.) and Other Legumes

Sulima

Zhukov

2022

Plants

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Grain legumes, or pulses, have many beneficial properties that make them potentially attractive to agriculture. However, the large-scale cultivation of legumes faces a number of difficulties, in particular the vulnerability of the currently available cultivars to various diseases that significantly impair yields and seed quality. One of the most dangerous legume pathogens is powdery mildew (a common name for parasitic fungi of the order Erisyphales). This review examines the methods of controlling powdery mildew that are used in modern practice, including fungicides and biological agents. Special attention is paid to the plant genetic mechanisms of resistance, which are the most durable, universal and environmentally friendly. The most studied legume plant in this regard is the garden pea (Pisum sativum L.), which possesses naturally occurring resistance conferred by mutations in the gene MLO1 (Er1), for which we list here all the known resistant alleles, including er1-12 discovered by the authors of this review. Recent achievements in the genetics of resistance to powdery mildew in other legumes and prospects for the introduction of this resistance into other agriculturally important legume species are also discussed.

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Nodulation Induces Systemic Resistance of Medicago truncatula and Pisum sativum Against Erysiphe pisi and Primes for Powdery Mildew-Triggered Salicylic Acid Accumulation

Cited by 27 publications

References 145 publications

Systems Biology of Plant-Microbiome Interactions

Systems Biology of Plant-Microbiome Interactions

Induced systemic resistance -like responses elicited by rhizobia

War and Peas: Molecular Bases of Resistance to Powdery Mildew in Pea (Pisum sativum L.) and Other Legumes

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